EP0978709A2 - Liquid flow meter - Google Patents

Abstract

The flow meter (1) has a casing (2) with at least one inlet opening (3) and at least one outlet opening (4). The fluid flows through the casing. The meter also has at least one movable body (5), such as a ball, inside the casing. The ball is moved along a closed path (6) by the fluid flow, which causes an eddy. The travel of the ball along the closed path is detected, e.g. optically, magnetically or inductively.

Description

The invention relates to flow meters for liquids.

Numerous devices are known for the flow measurement of liquids work according to very different functional principles. In practice, rotor measuring devices are often used used in which a rotatably mounted rotor from the liquid flow in Direction of rotation is driven and its revolutions around its axis as a measure of the Flow rate or the flow rate can be detected. In the main The impeller counter used is the rotor as a propeller, turbine, gear or generally designed as an impeller. In addition, rotors are also off-center or tangentially flowed cylinders or disks.

Rotor measuring devices are easy to set up, but have the following disadvantages in particular on. There is usually a small distance between the rotor and the housing, in particular in order to keep the flow not detected by the rotor low and the measuring accuracy to increase. However, this can easily cause disruptive bodies or contamination jam between rotor and housing and impair the function. On the rotors deposits can form which lead to measurement errors and also the function can affect. Furthermore, the bearing friction reduces the measuring accuracy and leads to the fact that a reliable measurement is only possible from a certain flow, whereby the bearing friction can increase further over time due to deposits. Besides there is a risk with pivot bearings that thread-like interfering bodies in the liquid can wind the axis of rotation and thus brake or even block the rotor. To at To ensure a satisfactory function of rotary bearings, expensive bearing materials must be used are used, which disadvantageously increase the manufacturing costs.

From DE 2 026 131 A1 a rotor measuring device is also known, in which a cylindrical one The rotor is centered radially and axially within the housing by the liquid flow is, whereby the pivot bearings for the rotor can be omitted.

In this rotor measuring device too, the distance between the rotor and the housing is small, in particular there is an interaction to center the rotor by the liquid flow with the housing is required. Therefore, these rotor measuring devices are also very sensitive against impurities or interfering bodies. If the flow velocity is too low the axleless rotor is not properly centered or touches the housing, causing underneath a certain flow rate, a measurement is no longer possible or only very poorly is. To achieve self-centering of the rotor through the liquid flow, are several precisely calculated, circumferential liquid inlet and liquid outlet openings required for connection to an inlet respectively a process must be summarized and the manufacturing costs increase.

All known rotor measuring devices thus have the disadvantages, only from a certain one Flow to work, prone to failure and relatively expensive.

There are also numerous other types of flow meters, such as vortex meters, Induction, Coriolis or ultrasonic flow meters, which have a high accuracy and have a large measuring range, but very complex and corresponding are expensive and therefore cannot be considered for numerous applications.

The object of the present invention is to provide a flow meter for liquids create the inexpensive to manufacture, not prone to failure and insensitive to deposits is high accuracy, especially with low flow rates having.

According to the invention, this object is achieved by a flow meter for a liquid with a housing that has at least one inlet opening and at least one outlet opening has and is flowed through by the liquid, and at least one movable Body inside the housing, closed by the flow of liquid along it Path is moved, the orbits of the at least one body along the closed Path can be detected.

In this way, a sufficient distance between the at least one movable Body and housing are adhered to to prevent disruptive influences from contamination or to avoid interfering bodies. There is no axis of rotation for storage also no danger that thread-like disruptive bodies wrap around it and the function of the Flow meter affect. With the axis of rotation, the bearing friction and the additional costs and manufacturing costs for pivot bearings and especially for the bearing materials. Such a flow meter can be easily and inexpensively, for example manufacture from a two-part housing and a body arranged therein, all Parts can be made of inexpensive material because there are no special demands on the material properties be put. During the movement of the at least one body on its course it will regularly hit the inside of the case and possibly loosen existing deposits. In this way, the housing is self-cleaning and the at least one body in it, making the flow meter essential is less sensitive to deposits.

A safe flow measurement is already with a body moved by the flow possible. It can be used as a direct measure of the flow velocity and thus of the Flow the number of revolutions per unit of time can be used or as inversely proportional Measure the length of time for one or more rounds. But there can also be several Bodies are used, whereby more cycles are recorded per unit of time. To this By using multiple bodies, a higher resolution of the measurement can be achieved the same time period is reached.

The revolutions of the at least one body can be optically detected, for example by a transmission light barrier or a reflex light barrier. The necessary ones Optical components are inexpensive and can be easily used with an electronic one Connect control, which can also be set up inexpensively and in almost all devices are available in which a flow meter according to the invention, if appropriate to be installed. The body is through the non-contact optical detection advantageously not affected.

The circulation can also be recorded magnetically or inductively, for example by the body is made of a magnetic material or with a magnet is provided and its movements with a magnetic field sensor, in particular one Hall probe, a reed contact or an induction sensor can be detected. Such procedures also enable the safe detection of the circulations in the case of a non-transparent one Liquid, for example due to contamination, or due to a non-transparent Through the housing, if it is made of non-magnetizable material.

The at least one body can pass through the inner surfaces of the housing and / or through Obstacles arranged in the housing are forced onto the closed path become. For this purpose, a channel can be formed in the interior of the housing Restrictions hold back the at least one body, the restrictions at least in some places the liquid may be permeable to the outflow to allow the liquid. For example, this can be the focus of a flat round housing be arranged with an annular inside a cylinder around which the at least one body moves around in a channel, which from the top of the housing, the Bottom of the housing, the ring-shaped inside and the cylinder jacket is limited.

Therefore, the path can be determined by constructive measures. In particular can in this way the device for detecting the orbits and the path to each other so be arranged so that the at least one body is in any case close enough to the Device moved past, in order to be able to reliably record its rotations.

The liquid flow can instead form a vortex in the housing and the keep at least one body along the vertebra on a closed path. This can be due to the internal shape of the housing and the way in which the liquid enters the housing flows, can be reached. For this purpose, the inside of the housing can be cylindrical, and the liquid inlet can be arranged or aligned such that the liquid flows essentially tangentially. The liquid outlet can be in the cylinder wall be arranged or essentially centrally in the top or bottom of the cylinder. The manufacturing effort can be further reduced in this way.

The liquid advantageously flows through the at least one inlet opening in one flat angle to the closed path of the at least one body into the housing. In this way, a flow is generated along the path that the at least one Drives body. Particularly with small flows it is advantageous that one uniform and clearly directed flow for driving the at least one body is trained.

It is particularly advantageous if there is at least one obstacle inside the housing is arranged, through which the liquid can flow and a movement of the prevents at least one body towards the at least one outlet opening. So can on the one hand be avoided that the at least one body by the liquid flow is held at the outlet opening and stops moving, and on the other hand it can depend on the exact course of the liquid flow on a predetermined Web are held. The obstacles can be made as a wall with multiple openings are smaller than the at least one body, or as a wall with a slot-shaped opening or be formed with circular ribs, the width of which is smaller than the smallest dimension of the at least one body.

The path along which the at least one body and possibly also the liquid flow moved, is advantageously circular. This will result in low flow losses and achieved a low pressure drop in the flow meter.

The at least one body can advantageously have a spherical shape that is simple can be produced and at which the risk is small that the at least one body in The housing is caught, jammed or jammed.

In a further embodiment, the at least one body essentially has this same specific gravity as the liquid so that it floats in the liquid and can also be moved by a very low current. In such a case, too the installation position and orientation of the flow meter little or no Influence on its function. This will ensure a safe function and an accurate measurement in particular achieved even with low flow rates and any installation position.

Since no special requirements are placed on the material properties, can the parts are made of different materials, especially plastic. The flow meter according to the invention can for this reason and because of it simple construction also integrated into parts of a liquid-carrying device by forming its housing in part of the device. The part itself is preferably one that carries the liquid whose flow rate is to be measured, however was originally not designed as a flow meter, but to another Purpose was provided anyway. The housing of the flow meter can then be special advantageously be formed in this part in the liquid path, so that the Flow meter retrofitted in the liquid-carrying device without any special effort can be. This is particularly advantageous for plastic injection molded parts.

Such an integrated flow meter can be used in particular advantageously in a household appliance, in particular in a laundry treatment machine or a dishwasher. For those manufactured in large numbers Machines of the consumer goods industry depend on the use of such a flow meter, whose measurement results are used in the treatment processes in a significantly improving manner can be crucially dependent on the fact that it is cheap and inexpensive in the Machine can be used. As plastic parts in which the flow meter is integrated can come, for example, a water inlet body in laundry treatment machines or a detergent dispenser into consideration.

Fig. 1

ein Schnitt durch einen erfindungsgemäßen Durchflußmesser in einer Ebene der Bewegungsbahn des Körpers und

Fig. 2

eine seitliche Schnitansicht entlang der Schnittlinie A-A am erfindungsgemäßen Durchflußmesser.

Further details, features and advantages of the invention result from the following description of an exemplary embodiment with reference to the drawings. Show in it

Fig. 1

a section through a flow meter according to the invention in a plane of the movement path of the body and

Fig. 2

a sectional side view along the section line AA on the flow meter according to the invention.

1 shows a flow meter 1 according to the invention with a housing 2, which has an inlet opening 3 and an outlet opening 4 through which a liquid 9 in the housing flows in or out. The housing 2 is over a large section circular and has a bulge in the vicinity of the outlet opening 4. Internally of the housing 2 there is a freely movable body 5, which has the shape of a ball and has substantially the same specific gravity as the liquid 9.

In front of the outlet opening 4 there is an obstacle 8 in the form of a wall with regular arranged breakthroughs. The obstacle 8 extends in an arc with the same Curvature like the circular section of the housing 2 up to close to the inlet opening 3. In the drawing are exemplary only some of the parts of the obstacle 8 with a reference number Mistake. The breakthroughs of the obstacle 8 are dimensioned such that the free movable body 5 does not fit through it. The circular section of the inside the housing 2 forms a circular together with the obstacle 8 external limitation for the body 5.

Inside the housing 2 is a cylindrical obstacle 7 concentric to circular section of the housing 2 arranged. The cylindrical obstacle 7 extends over the entire height of the housing interior and limited together with the obstacle 8, the circular portion of the housing 2, the top and bottom the housing has a circular channel in which the body 5 is enclosed and can move along a closed path 6.

The liquid 9 flows through the inlet opening 3 essentially tangentially to the web 6 in the housing 2, causing a flow in the direction of arrow 13 around the obstacle 7 trains around. Through the outlet opening 4, which after about three quarters of a turn arranged in the flow direction behind the liquid-permeable obstacle 8 the liquid can flow out again. The entire housing 2 is included Liquid filled so that a circular around the cylindrical obstacle 7 Forms flow that moves the body 5 along the path 6 in the direction of arrow 13.

Fig. 2 shows the flow meter 1 cut along a section line A-A in Fig. 1. In In this view, a light transmitter is at the bottom left of the channel in which the body 5 is moving 10 and a light receiver 11 is arranged to the right of the channel. The light transmitter 10 transmits a light beam 12 through the channel that cuts the path 6 of the body 5 to the light receiver 11. The body 5 causes an interruption each time the web 6 rotates of the light beam 12, which is detected by the light receiver 11. The flow rate or the flow of the liquid 9 can from the number of revolutions per unit of time or the time for a certain number of revolutions by means of the light receiver 11 can be determined. To install the flow meter 1 in a liquid-carrying Device can housing 2 in an existing liquid-carrying Part in particular be made of plastic, so that the manufacturing costs continue is reduced.

The solution according to the invention thus creates a flow meter with which with a very low cost and manufacturing effort a high insensitivity to Contamination and disruptive bodies in the liquid as well as high measuring accuracy in particular can also be achieved with low flow rates.

Claims (13)

Flow meter (1) for a liquid (9) with a housing (2), the at least has an inlet opening (3) and at least one outlet opening (4) and from which Liquid (9) is flowed through, and at least one movable body (5) in the Interior of the housing (2) by the flow of liquid along a closed path (6) is moved, the revolutions of at least one Body (5) along the closed path (6) can be detected. Flow meter (1) according to claim 1, characterized in that the at least a body (5) through the inner surfaces of the housing (2) and / or through obstacles (7, 8), which are arranged in the housing (2), on the closed path (6) is forced. Flow meter (1) according to claim 1, characterized in that the Liquid flow in the housing (2) forms a vortex and at least a body (5) moves along the vertebra. Flow meter (1) according to one of claims 1 to 3, characterized in that that the liquid (9) through the at least one inlet opening (3) in a flat Angle to the closed path (6) of the at least one body (5) in the Flows into the housing (2). Flow meter (1) according to one of claims 1 to 4, characterized in that that at least one obstacle (8) is arranged inside the housing (2) by that the liquid (9) can flow through and that prevents the at least a body (5) reaches the at least one outlet opening (4). Flow meter (1) according to one of claims 1 to 5, characterized in that that the closed path (6) along which the at least one body (5) moved, is circular. Flow meter (1) according to one of claims 1 to 6, characterized in that that the at least one body (5) is spherical. Flow meter (1) according to one of claims 1 to 7, characterized in that that the at least one body (5) has substantially the same specific weight how the liquid has (9). Flow meter (1) according to one of claims 1 to 8, characterized in that that the revolutions of the at least one body (5) are optically detected. Flow meter (1) according to one of claims 1 to 9, characterized in that that the revolutions of the at least one body (5) are detected magnetically or inductively become. Flow meter (1) according to one of claims 1 to 10 in a liquid (9) device which has at least one part which guides the liquid (9), characterized in that the housing (2) of the flow meter (1) in which the Liquid (9) leading part of the device is formed. Flow meter (1) according to claim 11 in a liquid (9) leading Device, characterized in that the part carrying the liquid (9) in which the Housing (2) of the flow meter (1) is formed, is a plastic injection molded part. Flow meter (1) according to claim 11 in a liquid (9) leading Device, characterized in that the device is a household appliance, in particular a Laundry care device or a dishwasher.

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